DE69727771T2 - BRIDGE AMPLIFIER WITH THE LOADED RETURN - Google Patents

Description

The The present invention relates to a bridge amplifier circuit having a first and a second amplifier, each one signal input, a reference input and a Output to a switched between the outputs load an amplified input signal supply.

A such amplifier circuit is from the Data Handbook IC01b "Semiconductors for Radio and Audio Systems ", P. 1247, 1995 by Philips Semiconductors. In a bridge configuration this amplifier circuit, the TDA1516, used to switch between the outputs of the two amplifiers to control switched load. A disadvantage of the known bridge amplifier circuit consists in that offsets occur between the outputs of the two amplifiers can, which leads to, that a direct current flows through the load. This in turn has one unnecessary Power consumption result.

Out US Pat. No. 4,560,946 discloses a bridge amplifier circuit, as described in the preamble of claim 1.

The The invention has for its object, a bridge amplifier circuit with reduced Offset at the outputs to accomplish.

A Bridge amplifier circuit according to the invention comprises the features of claim 1.

The Invention is based on the realization that by creating a Compensation of the signal fluctuations at the reference input of the second amplifier a feedback path from the output of the first amplifier can be provided to the said reference input to an offset voltage between the two outputs to reduce. In this way, the advantage of the feedback path (i.e., reducing the offset voltages), without the usual disadvantage a feedback path to have to accept namely a reduced gain the amplifier circuit. An additional one Advantage of the present invention is that only signal fluctuations be compensated. This means that distortion components that are present in the output signal of the first amplifier, too at the said reference input and thus also at the output of the second amplifier available. These distortion components are now in common mode present on both sides of the load, which means that the distortion components be significantly reduced in the signal current through the load.

A embodiment the bridge amplifier circuit according to the invention is characterized in that the feedback path is an impedance includes and the compensation means a power source with a Current value, which is proportional to the input signal.

This is a simple implementation of the measures according to the invention. The insertion an impedance in the feedback path allows the Using a simple input signal dependent power source with coupled to the reference input to the signal fluctuations to reduce this input. By making this stream proportional to the input signal will be possible errors / distortions or offset in the output signal of the first amplifier, but not in the input signal IN are present, not reduced at the reference input. this has compensation for this, because on both sides of the Last available.

A embodiment the bridge amplifier circuit according to the invention is characterized in that the product of the impedance value and the current value chosen is that creates a voltage at the reference input of the second amplifier to one through the output of the first amplifier to said reference input significantly compensate for the supplied signal voltage. The the reference input together with the feedback impedance supplied Signal current leads to a voltage at the reference input, which is essentially the product from the resistance value and the signal current value. By doing the value of this product is substantially equal to the output voltage the second amplifier, but with opposite sign, is chosen, this output voltage at the reference input substantially compensated, whereby the gain of the Circuit is maximized. An additional advantage of this compensation is that the reference input now only with a voltage has to do, which has only small fluctuations, and not with a tension that over one wide range can go. This will cause the input circuit of the first amplifier considerably simplified.

An embodiment of the amplifier circuit according to the invention is characterized in that the gain of the first amplifier is higher than the gain of the second amplifier Ver. By providing the first amplifier with a higher gain than the second amplifier, the first amplifier will be driven faster to high output voltages than the second amplifier and will therefore be the amplifier with the greatest distortion. Due to the presence of the feedback path, this distortion is not reflected in the sig Since the feedback path ensures that a distortion component present in the output voltage of the first amplifier will also be present in the output voltage of the second amplifier. This distortion is thus present on both sides of the load and therefore will not be present in the current through the load. By doing so, the bridge amplifier circuit can be driven to produce slightly more output with less distortion than is possible in a bridge amplifier circuit in which the gains of both amplifiers are equal (or in which the gain of the second amplifier is higher than the gain of the first amplifier) amplifier).

The the above object and the above features of the present invention are from the following description of the preferred embodiments with reference to the drawings. Show it:

1 a circuit diagram of a known bridge amplifier circuit;

2 a circuit diagram of a first embodiment of a bridge amplifier circuit according to the invention;

3 a circuit diagram of a second embodiment of a bridge amplifier circuit according to the invention.

In The figures are identical parts with the same reference numerals Mistake.

In 1 a circuit diagram of a known bridge amplifier circuit is shown. The bridge amplifier circuit comprises a first amplifier 1 with a non-inverting signal input 101 , an inverting reference input 102 and an exit 103 , a second amplifier 2 with an inverting signal input 202 , a non-inverting reference input 201 and an exit 203 , a burden 3 and a reference voltage source 4 , The reference inputs 102 and 201 are with the reference voltage source 4 connected. The signal inputs 101 and 202 are connected together to receive an input signal IN. The input signal IN is through the first and second amplifiers 1 and 2 reinforced, working in a bridge configuration to achieve high gain. Weight 3 is between the outputs 103 and 203 connected. Although each amplifier receives the same reference voltage, it is still possible that due to, for example, mismatches between the two amplifiers, an offset voltage between the outputs 103 and 203 is available.

In 2 a circuit diagram of a first embodiment of a bridge amplifier circuit according to the invention is shown. 2 differs from the following 1 :

• - the reference input 201 of the second amplifier 2 is no longer with the reference voltage source 4 or the reference input 102 of the first amplifier 1 connected;
• - an impedance 5 is between the exit 103 of the first amplifier 1 and the reference input 201 of the second amplifier 2 connected;
• A signal power source 6 is with the reference input 201 of the second amplifier 2 connected. The current value of the signal current source 6 is proportional to the input signal. The sign of the through the signal power source 6 supplied current is such that it provides a signal voltage at the reference input 201 of the second amplifier 2 which is proportional in size but opposite in terms of sign or polarity to that of the output 103 of the first amplifier 1 over the impedance 5 supplied signal voltage is. In this way, the signal power source acts 6 as compensation means for reducing the signal fluctuations at said reference input 201 , Preferably, the product becomes the impedance value of the impedance 5 and the current value of the signal current source 6 so chosen, that of the first amplifier 1 delivered said signal voltage is substantially compensated. Now only those in the output signal of the first amplifier 1 existing distortion components and offset voltage to the reference input 201 of the second amplifier 2 fed back. This means that these unwanted components are now on both sides of the load 3 are present and thus substantially no related to these unwanted components current through the load 5 flows. Because the signal fluctuations at the reference input 201 are efficiently compensated, there is no feedback for signal fluctuations. In this way, the usual disadvantage of the feedback, namely a reduced gain, is no longer present, and the gain of the bridge amplifier circuit is substantially the same as the gain of the known bridge amplifier circuit without feedback. An additional advantage of the present invention is that the input circuit of the second amplifier 2 can be kept simple, since the input circuit does not have to handle large voltage fluctuations, for example, voltage fluctuations ranging from the positive supply voltage to the negative supply voltage and which are generated in response to a large input signal IN. In a preferred embodiment form is the gain of the first amplifier 1 slightly higher than the gain of the second amplifier 2 , At high input signal levels, this means that it is possible for the output voltage of the second amplifier 2 barely contains distortions while the output of the first amplifier 1 due to the higher gain of the first amplifier 1 contains some (or even strong) distortions. Due to the feedback, these distortions are fed back to the other end of the load and there will be no distortion in the current through the load 3 to be available. If the gains from both amplifiers were equal, and in this situation and in the previous situation, the sum of the gains of the amplifiers were the same, then both outputs may contain the same distortions, of which only the distortions in the output of the second amplifier 2 be compensated due to the feedback. Thus, although the overall gain is not changed, there will be less distortion in the signal due to the load 3 be present when the gain of the first amplifier 1 at least slightly higher than the gain of the second amplifier 2 , It is thus possible to obtain a higher total gain with reduced distortion compared to a circuit in which the gain of the second amplifier 2 the gain of the first amplifier 1 is equal to or greater than this.

In 3 a circuit diagram of a second embodiment of an amplifier circuit according to the invention is shown. The first and the second amplifier 1 and 2 are configured as operational amplifiers, each with corresponding feedback impedances 9 and 8th between the corresponding outputs 103 and 203 and the corresponding inverting signal inputs 101 and 202 are switched. The signal current sources 7 and 8th are with the signal inputs 101 respectively. 202 connected to supply signal currents to the respective signal inputs, wherein the current values are proportional to the input signal, but have opposite signs. The signal current sources 6 and 7 have the same sign. Here are the reference inputs 102 and 201 each non-inverting inputs. The product of the impedance value of impedance 5 and the current value of the signal current source 6 should preferably be substantially equal to the product of the impedance value of impedance 9 and the current value of the signal current source 7 be. The product of the impedance value of the impedance 10 and the current value of the signal current source 8th should preferably be lower than the other products mentioned above to provide lower signal gain at the output 203 as at the exit 103 to realize and thereby reduce the distortion.

The invention is not limited to the examples described above. For example, the signs of the inputs can all be reversed as long as the two amplifiers have gains with opposite signs. The reference voltage source 4 can be implemented in numerous ways, as this is not part of the present invention. In addition, the impedance needs 4 It can also be a coil or a combination of elements as long as it provides a finite impedance for direct current and together with the compensating means (at least) for a compensation of the output voltage of the first amplifier 1 at the reference entrance 201 of the second amplifier 2 provides. The impedances 9 and 10 may provide, through suitable impedance networks, a desired transfer function for the first and second amplifiers 1 and 2 be replaced. The impedance 5 may also be replaced by a suitable impedance network to provide a desired feedback characteristic as long as a finite impedance for DC is provided to reduce the offset.

Claims (4)

Bridge amplifier circuit with a first ( 1 ) and a second amplifier ( 2 ), each having a signal input ( 101 . 202 ), a reference input ( 102 . 201 ) and an output ( 103 . 203 ) to a load connected between the outputs ( 3 ) supply an amplified input signal, wherein a feedback path ( 5 ) is provided from the output of the first amplifier to the reference input of the second amplifier, characterized in that the bridge amplifier circuit compensating means ( 6 ) coupled to said reference input which is the non-inverting input of the second amplifier for deriving a signal voltage at the reference input of the second amplifier which is proportional in magnitude but opposite in polarity to a signal voltage which is from the output of the first amplifier is supplied in order to reduce the signal fluctuations caused by an output signal of the first amplifier at the reference input of the second amplifier. Bridge amplifier circuit according to claim 1, characterized in that the feedback means contain an impedance and the compensation means a power source with a current value proportional to the input signal is. Bridge amplifier circuit according to claim 2, characterized in that the product of the impedance value and the current value is chosen so that a voltage at the reference input of the second amplifier is provided to a through To significantly compensate for the signal voltage supplied to the output of the first amplifier to said reference input. Bridge amplifier circuit according to claim 1, 2 or 3, characterized in that the reinforcement of the first amplifier is higher as the reinforcement of the second amplifier.